JP2023104572A - Indoor unit for air conditioner - Google Patents

Abstract

To provide an indoor unit for an air conditioner, capable of reducing aerodynamic noise.SOLUTION: An indoor unit 10 for an air conditioner 1 includes a Sirocco fan 52 for delivering sucked air in the radial direction, and a casing storing the Sirocco fan 52. In the casing, there are provided a rectangular air outlet 58 for air delivered by the Sirocco fan 52 to be blown therefrom, and a tongue part 62 forming the lower edge of the air outlet 58. On an upper face 81 of the tongue part 62, a plurality of flat surfaces are provided including steps gradually lower as extending from the Sirocco fan 52 to the air outlet 58. On at least one flat surface at its edge located on the side of the air outlet 58, an irregular shape is provided in a planar view.SELECTED DRAWING: Figure 3

Description

The present invention relates to an indoor unit for an air conditioner.

Patent Literature 1 discloses a duct-type air conditioner indoor unit. In this air conditioner indoor unit, the duct connection flange connected to the air outlet of the air conditioner body can be freely moved to freely change the opening size of the air outlet. As a result, the indoor unit of this air conditioner can secure a constant wind speed by freely changing the opening area of the air outlet, and performs comfortable air conditioning.

JP 2008-249287 A

The present disclosure provides an air conditioning indoor unit that can reduce aerodynamic noise.

An indoor unit of an air conditioner according to the present disclosure includes a sirocco fan that radially sends out sucked air, and a casing that houses the sirocco fan, and the casing blows out the air that is sent out by the sirocco fan. and a tongue forming the lower edge of the outlet, and the upper surface of the tongue is provided with a plurality of flat surfaces having steps that become lower from the sirocco fan toward the outlet. An edge portion of at least one of the planes located on the outlet side is provided with an uneven shape in a plan view.

According to the present disclosure, aerodynamic noise can be reduced.

Cross-sectional view along the rotation axis of the sirocco fan of the indoor unit provided in the air conditioner according to Embodiment 1 of the present disclosure Longitudinal cross section of indoor unit Perspective view of blower Perspective view of the tongue viewed from the front Perspective view of tongue A diagram schematically showing the airflow at the outlet when the blower is driven. A diagram schematically showing the airflow at the outlet when the blower is driven. A scatter diagram showing the relationship between the ratio of the height difference between the high step surface and the low step surface to the width of the low step surface and the air volume of the blower. A scatter diagram showing the relationship between the ratio of the width dimension of the recess along the direction in which the tongue extends and the width dimension of the recess along the direction from the outlet to the sirocco fan, and the air volume of the blower.

(Knowledge, etc. on which this disclosure is based)
At the time when the inventors came up with the present disclosure, there was a technology related to an indoor unit of a duct-type air conditioner that performs comfortable air conditioning. In this air conditioner indoor unit, the duct connection flange connected to the air outlet of the air conditioner body can be freely moved to freely change the opening size of the air outlet. Thereby, the indoor unit of this air conditioner can secure a constant wind speed by freely changing the opening area of the outlet.
A blower equipped with a sirocco fan is used as an indoor unit of this air conditioner. As such an air blower, there is known one that includes a casing that houses a sirocco fan, and that blows out air sent out by the sirocco fan from an air outlet provided in the casing.

By the way, in the blower as described above, the air sent out by the sirocco fan may collide with the lower edge of the outlet, thereby generating a vortex. The inventors have discovered a problem that in a blower or an air conditioner equipped with the blower, so-called aerodynamic noise may be generated when the air is blown out from the outlet while the vortex is generated. , came to constitute the subject matter of the present disclosure in order to solve the problem.
Accordingly, the present disclosure provides an air conditioner and a fan capable of reducing aerodynamic noise.

Hereinafter, embodiments will be described in detail with reference to the drawings. However, more detailed description than necessary may be omitted. For example, detailed descriptions of well-known matters or redundant descriptions of substantially the same configurations may be omitted. This is to avoid the following description from becoming more redundant than necessary and to facilitate understanding by those skilled in the art.
It should be noted that the accompanying drawings and the following description are provided to allow those skilled in the art to fully understand the present disclosure and are not intended to limit the claimed subject matter thereby.

(Embodiment 1)
Embodiment 1 will be described below with reference to FIGS. 1 to 4. FIG. In each figure, the symbol FR indicates the front of the indoor unit in a horizontally suspended state, the symbol UP indicates the upper side of the indoor unit, and the symbol LH indicates the left side of the indoor unit. In the following description, each direction is a direction along each direction of these indoor units.
[1-1. composition]
[1-1-1. Configuration of air conditioner]
FIG. 1 is a cross-sectional view along the rotation shaft 78 of the sirocco fan 52 of the indoor unit 10 provided in the air conditioner 1. FIG. This FIG. 1 is a plan view of a cross section along the front-rear direction and left-right direction of the indoor unit 10 passing through the rotating shaft 78 of the sirocco fan 52 .

As shown in FIG. 1 , the air conditioner 1 of this embodiment includes an indoor unit 10 . The air conditioner 1 includes a heat exchanger 69 housed in the indoor unit 10, a pressure reducing device such as a compressor and an electronic expansion valve housed in the outdoor unit, and an outdoor heat exchanger. Equipped with a refrigeration cycle. Then, in the air conditioner 1, a predetermined space to be conditioned is air-conditioned by circulating the refrigerant in this refrigeration cycle.

The indoor unit 10 is an indoor unit of a duct-type air conditioner 1 installed in a ceiling space, inside a wall, or under a floor. The indoor unit 10 is provided so that the arrangement direction can be changed so that the blowing direction can be changed according to the installation location. For example, when blowing air in the horizontal direction, the indoor unit 10 is installed in a so-called flat hanging state in which the discharge port 18 for blowing conditioned air is positioned on the side. Further, when air is blown upward, the indoor unit 10 is installed in a so-called vertically suspended state in which the air outlet is positioned upward.
In the following description, the vertical direction means the vertical direction when the indoor unit 10 is installed in a horizontally suspended state.

FIG. 2 is a longitudinal sectional view of the indoor unit 10. FIG. FIG. 2 is a cross-sectional view taken from the left side of the indoor unit 10 along the longitudinal direction and the vertical direction of the indoor unit 10 and passing through a position avoiding the plurality of blowers 35 .
As shown in FIGS. 1 and 2, the indoor unit 10 includes a housing 19 composed of a front plate 11, a rear plate 12, a pair of side plates, namely a right side plate 13 and a left side plate 14, a bottom plate 15, and a top plate 16. have. The front plate 11 is provided with a discharge port 18, which is an opening, over the entire left-right direction. Further, the back plate 12 is provided with a suction port 59 that is an opening.

The internal space of the housing 19 is partitioned into a blowing chamber 22 and a heat exchange chamber 23 by a partition plate 21 .
The partition plate 21 is a flat member having a predetermined length. Both ends of the partition plate 21 in the longitudinal direction are connected to substantially the center of each of the right side plate 13 and the left side plate 14 .

A plurality of blowers 35 and electric motors 54 are arranged side by side in the left-right direction of the indoor unit 10 in the blower chamber 22 .
Each blower 35 comprises a sirocco fan 52 and a scroll casing 56 . The sirocco fan 52 is a so-called centrifugal fan that sends out air. These sirocco fans 52 are supported by a rotating shaft 78 extending in the horizontal direction of the indoor unit 10 . That is, the sirocco fans 52 included in each blower 35 are connected to each other via the rotation shaft 78 . The scroll casing 56 is a casing that houses the sirocco fan 52 . The scroll casing 56 is provided with an opening 57 for taking in air by the rotation of the sirocco fan 52, and a duct-like blowing part 65 for guiding the air taken in and then sent out by the sirocco fan 52 in a predetermined direction.

The electric motor 54 is connected to a rotating shaft 78 of the sirocco fan 52 and rotates the sirocco fan 52 via this rotating shaft 78 .
As shown in FIG. 1, in this embodiment, three fans 35 are arranged in the blower chamber 22 . Note that the configuration of FIG. 1 is an example, and the indoor unit 10 may be provided with any number of electric motors 54 and blowers 35 .

The partition plate 21 is provided with a plurality of communication openings 25 communicating with the air blowing chamber 22 and the heat exchange chamber 23 , and the air blowing section 65 of the air blower 35 is joined to each of the communication openings 25 . Also, the opening 57 of the blower 35 opens into the blowing chamber 22 .

When the blower 35 operates, the blower 35 draws air from the blower chamber 22 through the suction port 59 , and the outside air flows into the blower chamber 22 . The outside air is sent to the heat exchange chamber 23 by the air blower 35 through the communication opening 25 formed in the partition plate 21 .
That is, in the indoor unit 10, the blower chamber 22 is the space on the primary side of the blower 35, and the heat exchange chamber 23 is the space on the secondary side.

A heat exchanger 69 is arranged in the heat exchange chamber 23 . The heat exchanger 69 is a utilization side heat exchanger that functions as an evaporator that evaporates the refrigerant supplied from the outdoor unit or a condenser that condenses the refrigerant.

The heat exchanger 69 of the present embodiment is a so-called fin-and-tube heat exchanger, and the heat exchanger 69 has a plurality of metal fins joined to a copper refrigerant pipe, and has an elongated shape as a whole. It is formed in a plate shape.
Refrigerant sent from the outdoor unit flows into one end of this refrigerant pipe. The inflowing refrigerant flows through the entire heat exchanger 69 through the refrigerant pipe and flows out from the other end of the refrigerant pipe to the outdoor unit again.

As shown in FIG. 1, the heat exchanger 69 is arranged such that its longitudinal direction extends along the lateral direction of the heat exchange chamber 23 . One plane of the heat exchanger 69 arranged in this manner faces the partition plate 21 and each air blowing section 65 , and the other plane faces the discharge port 18 . Thereby, the refrigerant pipes of the heat exchanger 69 extend along the longitudinal direction of the partition plate 21 , and the fins are arranged so that the plate thickness direction of each fin extends along the longitudinal direction of the partition plate 21 .

The air sent to the blowing chamber 22 by the blower 35 exchanges heat with the refrigerant flowing through the refrigerant pipes when passing through the heat exchanger 69 mainly through the gaps between the fins, and the air discharged from the front plate 11 is discharged. It is blown out from the outlet 18 .
Note that the indoor unit 10 may include a plurality of heat exchangers. Also, these heat exchangers may be arranged arbitrarily in the heat exchange chamber 23 .

[1-1-2. Configuration of blower]
FIG. 3 is a perspective view of the blower 35. FIG.
Next, the configuration of the blower 35 will be described in detail.
As shown in FIG. 3 , the blower 35 includes a sirocco fan 52 that radially exhausts air, and a scroll casing 56 that houses the sirocco fan 52 .
The sirocco fan 52 is an impeller formed in a drum shape or a cylindrical shape having a disc-shaped main plate 71 and a large number of blades erected on the peripheral edge of the main plate 71 . A rotating shaft 78 is inserted through substantially the center of the main plate 71 .

The scroll casing 56 is provided with a casing main body 60 that houses the sirocco fan 52 and a blower portion 65 that protrudes from the casing main body 60 in one direction.
The casing main body 60 includes a pair of side plates 72 located in the rotation axis direction of the sirocco fan 52 . As described above, each side plate 72 is provided with an opening 57 opening in the rotation axis direction of the sirocco fan 52 . The blower 35 sucks air from the opening 57 by the rotation of the sirocco fan 52 .

The air blowing portion 65 is formed in a duct shape and includes an upper surface portion 61 forming the upper surface of the air blowing portion 65, a tongue portion 62 forming the lower surface, and a pair of side surface portions 63 forming left and right side surfaces. Each side surface portion 63 is a flat plate portion continuous with each side plate 72 .

A blowout port 58 is provided at the end of the air blower 65 located on the side opposite to the casing main body 60 . The air outlet 58 is a rectangular opening formed by the ends of the upper surface portion 61 , the tongue portion 62 , and the pair of side surface portions 63 located on the front side of the indoor unit 10 .
The air blower 65 and the air outlet 58 are provided facing the side peripheral surface of the sirocco fan 52 . In other words, the air blower 65 and the blower outlet 58 are arranged in the centrifugal direction of the sirocco fan 52 . The air sent out by the sirocco fan 52 is blown out from the inside of the scroll casing 56 to the outside through the blowout port 58 .

[1-1-3. Configuration of tongue]
The tongue portion 62 is arranged in the air blowing portion 65 so as to face the plane of the upper surface portion 61 and forms the lower edge of the air outlet 58 . This tongue 62 extends from one side 63 to the other side 63 . The tongue portion 62 has a predetermined width dimension along each of the up-down direction and the front-rear direction of the indoor unit 10 . An upper surface 81 of the tongue portion 62 is formed in a rectangular shape in plan view.

FIG. 4 is a perspective view of the tongue portion 62 viewed from the front. 5 is a perspective view of the tongue 62. FIG. FIG. 5 omits part of the tongue portion 62 in the horizontal direction of the indoor unit 10 .
As shown in FIGS. 4 and 5 , the upper surface 81 is provided with a plurality of flat surfaces 83 that decrease in a so-called stepped manner from the sirocco fan 52 toward the outlet 58 . In this embodiment, two planes 83 are provided. By providing these two flat surfaces 83 , the upper surface 81 is provided with a step portion 80 . The stepped portion 80 extends along the vertical direction of the indoor unit 10 , and the two planes 83 are parallel to the upper surface portion 61 .
Hereinafter, among the two planes 83, the plane 83 located on the sirocco fan 52 side of the upper surface 81 is referred to as a high stage surface 82, and the plane 83 located on the blowout port 58 side, in other words, the high stage surface 82 is located on the blowout port 58 side. A plane 83 adjacent to is a low step surface 84 .

The high step surface 82 and the low step surface 84 are adjacent to each other, and the height dimension at which the high step surface 82 is positioned is relatively higher than the height dimension at which the low step surface 84 is positioned in the vertical direction of the indoor unit 10 . formed high. Both the plane 83 and the upper surface 85 are flat surfaces substantially parallel to the upper surface portion 61 .

In the present embodiment, the edge portion 97 of the low step surface 84 located on the blowout port 58 side is provided with an R shape. As a result, when the air sent to the sirocco fan 52 is blown out from the blow-out port 58, it is blown out while gently deflecting downward along the R shape. Therefore, it is possible to reduce the air vortex caused by the air pressure gradient between the inside and outside of the scroll casing 56 .

The dimension of the height difference between the high step surface 82 and the low step surface 84 is longer than the width dimension of the low step surface 84 in the direction from the outlet 58 toward the sirocco fan 52 and 1.5 times the width dimension of the high step surface 82 . Formed less than 5 times.
As a result, the air sent out from the sirocco fan 52 flows along the high stage surface 82 and then descends and flows along the low stage surface 84 . Therefore, in the space surrounded by the step portion 80 and the low step surface 84 , the air gradually joins with the air outside the scroll casing 56 having a large pressure gradient, thereby reducing the vortex.

Hereinafter, the dimension of the height difference between the high step surface 82 and the low step surface 84 is defined as the height dimension H, and the width dimension of the low step surface 84 along the direction from the air outlet 58 to the sirocco fan 52 is defined as the width dimension L1 ( Figure 6). For convenience of explanation, the space surrounded by the step portion 80 and the low step surface 84 and facing the outlet 58 is defined as a space S. As shown in FIG.

The high step surface 82 is provided with a plurality of recesses 89 recessed toward the sirocco fan 52 from an edge portion 87 located on the blowout port 58 side in plan view. A plurality of recesses 89 are provided over the entire longitudinal direction of the tongue portion 62 and over the entire height direction of the step portion 80 . Each concave portion 89 is formed in a substantially V shape in which the width dimension becomes narrower from the edge portion 87 toward the sirocco fan 52 on the plane 83 . By providing the plurality of concave portions 89 , the edge portion 87 has an uneven shape in a plan view of the upper surface 81 .

In the edge portion 87 , the width dimension of each recessed portion 89 from the edge portion 87 toward the sirocco fan 52 is longer than the width dimension of each recessed portion 89 along the longitudinal direction of the tongue portion 62 . It is formed to be four times or less the width dimension of the recess 89 .
Thereby, the recessed portion 89 can have a width dimension capable of dividing the air sent out from the sirocco fan 52 . For this reason, the air is suppressed from continuing at the tongue portion 62, and the vortex generated in the air can be made finer.

Hereinafter, the width dimension of the recessed portion 89 along the direction in which the tongue portion 62 extends is defined as the width dimension W, and the length dimension of the recessed portion 89 along the direction from the outlet 58 toward the sirocco fan 52 is defined as the length dimension L2 (FIG. 6). .

By providing these concave portions 89 , the edge portion 87 is provided with a convex portion 86 in which the tip 91 protrudes from the sirocco fan 52 side toward the low step surface 84 and the outlet 58 . The convex portion 86 is formed in a substantially V shape whose width dimension is narrowed from the sirocco fan 52 toward the outlet 58 . A tip 91 of the projection 86 and a projection side 95 that is a pair of sides located on both sides of the tip 91 form part of the edge 87 .

The projection side 95 is part of the edge 87 and one side of the plane 83 . These projection sides 95 form the sides of the upper end positioned on both sides of the tip 91 and correspond to the sides positioned on both sides of the recess 89 . These protruding portion sides 95 are oblique sides when the tongue portion 62 is viewed from above because the protruding portion 86 is formed in a substantially V shape.

[1-2. motion]
[1-2-1. Operation of air conditioner]
The operation of the air conditioner 1 configured as described above will be described below.
In the air conditioner 1, the operation of the blower 35 causes the air sucked from the suction port 59 to flow into the scroll casing 56 from the opening 57 along the rotation axis direction. The air blower 35 blows out the inflowing air from the air blowing section 65 to the heat exchanger 69 . The blown air undergoes heat exchange in the heat exchanger 69 to become conditioned air, and is discharged from the discharge port 18 into the space to be conditioned.

FIG. 6 is a diagram schematically showing the airflow A at the outlet 58 when the blower 35 is driven. FIG. 6 schematically shows a part of the longitudinal section of the air blower 65 along the longitudinal direction of the indoor unit 10. As shown in FIG. In FIG. 6, for convenience of explanation, the airflow A, which is the flow of air sent out by the blower 35, is indicated by a dashed line. Moreover, in FIG. 6, the space S is indicated by a two-dot chain line.
The air blown out by the blower 35 is sent out in the radial direction of the sirocco fan 52 by the sirocco fan 52 , passes through the air blower 65 , and goes to the blowout port 58 . At this time, part of the air is obliquely blown down from the upper surface portion 61 side toward the upper surface 81 as shown in FIG.

In the conventional air conditioner, the upper surface 81 is a flat surface, and the airflow A, which is the flow of air that is blown down, collides with the upper surface 81 and is deflected so as to be substantially parallel to the upper surface 81 and toward the outlet 58. flow towards. At this time, in the conventional air conditioner, a plurality of vortices are generated in the airflow A, and the vortices flow along the upper surface 81 and increase.
Furthermore, when the edge portion 97 located on the outlet 58 side of the upper surface 81 is linear, a plurality of vortices are connected along the longitudinal direction of the upper surface 81 and may increase.

Here, in the blower 35 to be driven, the inside of the scroll casing 56 , particularly the inside of the blowing section 65 , and the outside of the scroll casing 56 such as the heat exchange chamber 23 are closer to the outside of the scroll casing 56 than the inside of the blowing section 65 . The speed of the airflow A is faster than Therefore, in the air conditioner 1 , a pressure gradient is generated in which the pressure inside the blower section 65 is higher than the pressure outside the scroll casing 56 . As a result, in the conventional air conditioner, when air is blown out of the scroll casing 56 from the inside of the high-pressure air blowing section 65 through the blowout port 58, the vortex generated in the airflow A is caused by the pressure gradient. could increase further.
In this way, the vortex generated and increased by driving the blower 35 may increase so-called aerodynamic noise by contacting the heat exchanger 69, for example.

In this embodiment, as shown in FIG. 6, the upper surface 81 is provided with a high step surface 82 and a low step surface 84 . Due to the provision of the high step surface 82 and the low step surface 84 , part of the airflow A flows down the high step surface 82 and the low step surface 84 . As a result, the airflow A is blown out from the outlet 58 without colliding with the upper surface 81, that is, without being deflected. As a result, in the blower 35 , the occurrence of a vortex caused by the airflow A colliding with the upper surface 81 is suppressed.

Furthermore, a space S is provided in the upper surface 81 . The pressure in this space S is an intermediate pressure between the relatively high pressure inside the blowing section 65 and the relatively low pressure outside the scroll casing 56 . For this reason, part of the airflow A descends the steps 80 and flows through the space S, thereby gradually joining the air provided with the pressure outside the scroll casing 56 . That is, in the blower 35 , the pressure gradient between the inside of the blower section 65 and the outside of the scroll casing 56 is alleviated by the space S.
As a result, in the blower 35, the generation of vortices generated in the airflow A is suppressed. In addition, in the blower 35, even if the airflow A collides with the upper surface 81, the vortex increases by descending the high step surface 82 and the low step surface 84 and flowing through the space S. Suppressed.

FIG. 7 is a diagram schematically showing the airflow A at the outlet 58 when the blower 35 is driven. FIG. 7 is a schematic plan view of the tongue portion 62. As shown in FIG. In FIG. 7, for convenience of explanation, the airflow A, which is the flow of air sent out by the blower 35, is indicated by a dashed line.
As shown in FIG. 7, the airflow A flowing along the upper surface 81 is split by the protrusion side 95 when descending the high step surface 82 and the low step surface 84 . Along with this, the vortex generated by the airflow A colliding with the upper surface 81 is similarly cut off by the projection side 95 and is reduced and made finer. This suppresses the increase of the vortex in the blower 35 .

Furthermore, in the present embodiment, since the recessed portion 89 is formed in a substantially V-shape, it extends along the longitudinal direction of the tongue portion 62 from the side of the sirocco fan 52 toward the side of the low stage surface 84 and the side of the outlet 58 . width dimension increases. Since the recessed portion 89 is continuous with the space S, the airflow A divided by the projecting portion side 95 descends the high step surface 82 and the low step surface 84 as the width dimension of the recessed portion 89 increases. It flows into the space S step by step. As a result, in the blower 35 , an increase in vortices due to the pressure gradient between the inside of the blower section 65 and the outside of the scroll casing 56 is suppressed.

In addition, in the blower 35, the airflow A is guided further downward by the high stage surface 82, the low stage surface 84, and the recesses 89, so that the air volume below the outlet 58 can be increased. It is possible to improve the distribution of the air volume in the vertical direction of the outlet 58 . In the indoor unit 10, unevenness in air flow velocity in the vertical direction of the heat exchanger 69 is suppressed, and heat exchange efficiency can be improved.

[1-2-2. Air conditioner experiment]
Next, an experiment conducted by the inventors to analyze the relationship between the structure of the tongue portion 62 of the blower 35 and the air volume in this embodiment will be described.
FIG. 8 is a diagram showing the relationship between the ratio between the height dimension H of the height difference between the high step surface 82 and the low step surface 84 and the width dimension L1 of the low step surface 84 and the air volume of the blower 35 . In FIG. 8 , the horizontal axis X1 indicates the ratio of H/L1, and the vertical axis Y indicates the air volume of the blower 35 .
The inventors changed the ratio between the height dimension H and the width dimension L1, and measured the air volume for each ratio at a predetermined number of rotations of the blower 35 .

The plots in FIG. 8 show the results obtained by the measurements described above. In FIG. 8, the curve e2 is an approximated curve of each plot, and the dashed line e1 is the air volume of the conventional blower. From the results shown in FIG. 8, the inventors found that when the ratio between the height dimension H and the width dimension L1 satisfies the following formula (1), the blower 35 has a larger air volume at the same rotation speed than the conventional blower. It was found that it is possible to send out
0<H/L1≤1.5 (1)

By satisfying the above formula (1), a part of the airflow A sent to the blower 35 does not pass over the low stage surface 84 and blow out from the outlet 58, After stepping down, the air is blown out from the outlet 58. - 特許庁Then, the airflow A flows through the space S, and the pressure gradient between the inside of the air blower 65 and the outside of the scroll casing 56 is reduced by the space S, and an increase in the vortex of the airflow A is suppressed.
Based on the above measurements, the inventors have found that it is desirable that the height dimension H is 5 mm and the average width dimension L1 is 6.5 mm.

9 shows the relationship between the ratio of the width dimension W of the recessed portion 89 along the direction in which the tongue portion 62 extends and the length dimension L2 of the recessed portion 89 along the direction from the outlet 58 to the sirocco fan 52, and the air volume of the blower 35. It is a figure which shows. 8, the horizontal axis X2 indicates the ratio of L2/W, and the vertical axis Y indicates the air volume of the blower 35. In FIG.
The inventors changed the ratio between the width dimension W of the recessed portion 89 along the direction in which the tongue portion 62 extends and the length dimension L2 of the recessed portion 89 along the direction from the outlet 58 toward the sirocco fan 52, The air volume was measured for each ratio at a predetermined number of revolutions.

The plots in FIG. 9 show the results obtained by the measurements described above. In FIG. 9, curve e3 is an approximated curve for each plot, and dashed line e1 is the air volume of the conventional blower. From this result, the inventors found that when the ratio of the width dimension W to the length dimension L2 satisfies the following expression (2), the blower 35 can send out a larger air volume at the same rotation speed than the conventional blower. It is possible to obtain the knowledge.
0<L2/W≤4 (2)

By satisfying the above formula (2), in the blower 35, as the high step surface 82 and the low step surface 84 descend, the vortex generated in the airflow A is divided by the protruding portion side 95 and A series of vortices and blowing out from the outlet 58 is suppressed.
Based on the above measurements, the inventors have found that it is desirable that the width dimension W is 24 mm and the length dimension L2 is 6 mm.

In this way, by satisfying the above formulas (1) and (2), the blower 35 can reduce the aerodynamic noise more than the conventional blower when sending out substantially the same amount of air. In other words, by satisfying the above formulas (1) and (2), the blower 35 can send out a larger amount of air with a lower input while suppressing aerodynamic noise more than the conventional blower.

[1-3. effects, etc.]

As described above, in the present embodiment, the air conditioner 1 includes the sirocco fan 52 that radially sends out the sucked air, and the scroll casing 56 that houses the sirocco fan 52 . The scroll casing 56 is provided with a rectangular air outlet 58 through which the air sent out by the sirocco fan 52 is blown, and a tongue portion 62 forming the lower edge of the air outlet 58 . An upper surface 81 of the tongue portion 62 is provided with a plurality of flat surfaces 83 having steps that become lower from the sirocco fan 52 toward the outlet 58 . At least one edge portion 87 of the plane 83 located on the side of the sirocco fan 52 among the plurality of planes 83 is provided with an uneven shape in plan view.

As a result, in the blower 35, the air that has collided with the tongue portion 62 descends the high stage surface 82 and the low stage surface 84 and joins the air outside the scroll casing 56, which has a large pressure gradient, step by step. Therefore, the air blower 35 can reduce air vortices that are generated and increase due to the pressure gradient.
In addition, in the blower 35 , the air impinging on the tongue 62 descends the high stepped surface 82 and the low stepped surface 84 and is divided by the projecting portion sides 95 formed by the recessed portion 89 . Therefore, in the blower 35, the vortex generated by the air colliding with the tongue portion 62 is divided, reduced, and finely divided, so that the aerodynamic noise can be reduced.

As in the present embodiment, at least one of the flat surfaces 83 of the blower 35 is provided with a V-shaped concave portion 89 in a plan view.
As a result, the airflow A divided by the projection side 95 flows into the space S in stages while descending the high step surface 82 and the low step surface 84 as the width dimension of the recess 89 increases. Therefore, in the blower 35 , an increase in vortices due to the pressure gradient between the inside of the blower section 65 and the outside of the scroll casing 56 is suppressed.

As in the present embodiment, the dimension of the height difference between the high step surface 82 and the low step surface 84 is defined as the height dimension H, and the width of the low step surface 84 along the direction from the outlet 58 toward the sirocco fan 52 is When the dimension is the width dimension L1, each may satisfy the following relationship.
0<H/L1≤1.5

As a result, part of the airflow A sent out to the blower 35 descends the high stage surface 82 and the low stage surface 84 and flows through the space S. The pressure gradient with the outside of the is relaxed. Therefore, in the blower 35, the increase of the vortex of the airflow A is suppressed, and the aerodynamic noise is reduced.

As in the present embodiment, at least one of the planes 83 is provided with a plurality of recesses 89 along the direction in which the lower edge of the blower outlet 58 extends. Assuming that the width dimension of the recess 89 is the width dimension W and the length dimension of the recess 89 along the direction from the outlet 58 toward the sirocco fan 52 is the length dimension L2, the following relationships may be satisfied.
0<L2/W≤4

As a result, in the blower 35, the vortices generated in the flow A are divided by the protruding portion sides 95 as each stepped portion 80 descends, and the vortices are prevented from being continuously blown out from the outlet 58. be. Therefore, in the blower 35, aerodynamic noise is reduced.

(Other embodiments)
As described above, Embodiment 1 has been described as an example of the technology disclosed in the present application. However, the technology in the present disclosure is not limited to this, and can also be applied to embodiments with modifications, replacements, additions, omissions, and the like. Also, it is possible to combine the constituent elements described in the first embodiment to form a new embodiment.
Therefore, other embodiments will be exemplified below.

In the first embodiment, the upper surface 81 is provided with two flat surfaces 83, but this is not limiting, and the flat surface 83 located on the blowout port 58 side is located closer to the sirocco fan 52 than the flat surface 83. More than two planes 83 may be provided, provided they are relatively lower than the planes 83 .

In Embodiment 1 described above, the concave portion 89 is not limited to the V-shape, and may have other shapes such as a rectangle, an arc, and a curve. In addition, the tip 91 may be rounded or chamfered.

Similarly, each protrusion 86 may have any shape as long as it satisfies the above equations (1) and (2) and has a pair of protrusion sides 95 . Moreover, each convex portion 86 may have different shapes and sizes depending on the arrangement position in the longitudinal direction of the tongue portion 62 as long as the above formulas (1) and (2) are satisfied.

In Embodiment 1 above, stepped portion 80 extends along the vertical direction of indoor unit 10 , and each flat surface 83 is parallel to upper surface portion 61 . However, the present invention is not limited to this, and if the plane 83 located on the side of the outlet 58 is at a position relatively lower than the plane 83 located on the side of the sirocco fan 52 than the plane 83, each plane 83 has a predetermined angle. It may have an inclination or an R shape.

For example, plane 83 may be provided with a slope or radius. As a result, the air sent out to the sirocco fan 52 flows along the plane 83 while descending, so that the air blown out from the air outlet 58 is diffused downward. Therefore, in the indoor unit 10, the flow velocity of the air sent out to the lower part of the heat exchanger 69 increases, and the imbalance of the air flow velocity in the vertical direction of the heat exchanger 69 is suppressed, so that the heat exchange efficiency can be improved. be.

Further, for example, the plane 83 located on the blowout port 58 side may be formed at an angle inclined downward from the plane 83 located on the sirocco fan 52 side. As a result, the air that has descended from the plane 83 is gradually deflected downward and diffused toward the outlet 58 . Therefore, in the indoor unit 10, sharp deflection of the air due to collision with the upper surface 81 can be suppressed, and the pressure loss associated with the deflection can be reduced.

Note that the above-described embodiment is for illustrating the technology in the present disclosure, and various changes, replacements, additions, omissions, etc. can be made within the scope of the claims or equivalents thereof.

INDUSTRIAL APPLICABILITY The present disclosure is applicable to air conditioners including indoor units provided with sirocco fans. Specifically, the present disclosure is applicable to ceiling-embedded duct-type indoor units, refrigeration cycle devices such as ceiling-mounted indoor units and floor-standing indoor units, drying devices, air supply/exhaust ventilation devices, and the like.

1 air conditioner 10 indoor unit 35 blower 52 sirocco fan 56 scroll casing (casing)
58 outlet 62 tongue 80 stepped portion 81 upper surface 83 flat surface 82 high step surface (flat surface)
84 Low step surface (plane)
87 Edge 89 Recess A Airflow H Height dimension L1, W Width dimension L2 Length dimension S Space

Claims (4)

A sirocco fan that sends out the inhaled air in a radial direction,
A casing in which the sirocco fan is housed,
The casing includes an air outlet through which the air sent out by the sirocco fan is blown;
A tongue portion forming the lower edge of the outlet is provided,
The upper surface of the tongue is provided with a plurality of flat surfaces having steps that become lower from the sirocco fan toward the outlet,
An indoor unit of an air conditioner, wherein an edge portion of at least one of the planes located on the outlet side is provided with an uneven shape in plan view. The indoor unit of an air conditioner according to claim 1, wherein the uneven shape is V-shaped. Among the plurality of planes,
Let H be the dimension of the height difference between a high step surface, which is a plane on which the uneven shape is provided, and a low step surface, which is a plane adjacent to the high step surface on the outlet side,
When the width dimension of the low stage surface along the direction from the air outlet toward the sirocco fan is L1,
3. The indoor unit of an air conditioner according to claim 1, wherein each satisfies the following relationships.
0<H/L1≤1.5 Let W be the width dimension along the direction in which the tongue portion of at least one concave portion provided by the uneven shape extends,
When the width dimension of the recess along the direction from the outlet to the sirocco fan is L2,
The indoor unit of the air conditioner according to any one of claims 1 to 3, wherein each satisfies the following relationships.
0<L2/W≤4

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